Modelling the Future of Gaia Neutron Star-Main Sequence Binaries: From Eccentric Orbits to Millisecond Pulsar-White Dwarfs
Abstract
We model the evolution of 21 Gaia neutron star (NS)-main-sequence binaries (orbital period Porb200--1000 days, eccentricity e0.2) using binary evolution with MESA. We examine eccentric mass transfer and models assuming prior circularization. All systems end as NS-white dwarf (WD) binaries, but transfer modes yield distinct outcomes. Under eccentric transfer, binaries are driven to higher e, forming orbits with e0.6 and P orb1000-4000 days. Periastron bursts are brief (106 yr), transfer only a few ×10-2 M, and produce mildly recycled pulsars (Pspin50 ms) with low-mass He WDs. Artificially circularized transfer gives P orb200-2000 days, lasts 107 yr, and allows NSs to accrete 0.1 M, forming fully recycled MSPs (Pspin few-30 ms) with CO WDs. Allowing super-Eddington accretion up to 100× the canonical rate makes even eccentric systems efficient MSP producers, though torque coupling remains uncertain. Using an adaptive, field-dependent magnetic-field decay timescale, we find MSPs stay radio-active over Gyr spans. Gaia systems undergoing stable mass transfer remain wide and fail to match the Galactic MSP-WD population, where most, nearly circular systems have P orb100 days. Binaries with different mass ratios and initial configurations -- likely leading to unstable mass transfer -- are needed to reproduce the observed MSP-WD distribution.
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